Shoju Hiraga

Expression of tenascin in human gliomas : its relation to histological malignancy, tumor dedifferentiation and angiogenesis

SummaryThe immunohistochemical distribution of tenascin (TN), fibronectin (FN), and laminin (LN) was investigated in 56 human gliomas (8 astrocytomas, 15 anaplastic astrocytomas, and 33 glioblastomas) with regards to the histological degree of malignancy and the degree of tumor cell differentiation evaluated by the staining of glial fibrillary acidic protein (GFAP). In 8 anaplastic astrocytomas and 28 glioblastomas, TN was predominantly immunolocalized in the basement membrane zone of the proliferating tumor vessels; sections of all astrocytomas were negative for TN staining. FN was localized in the basement membrane zone of the vessels in all astrocytomas, 12 anaplastic astrocytomas, and 22 glioblastomas. In 7 anaplastic astrocytomas and 19 glioblastomas, both TN and FN were expressed to various degrees in the tumor vessels. However, most of the TN-positive vessels did not express FN, and most of the FN-positive vessels were negative for TN staining. Furthermore, in 6 anaplastic astrocytomas and 12 glioblastomas, either TN of FN, but not both, were expressed in any area on serial sections. Most of the tumor cells around TN-positive, FN-negative tumor vessels did not express GFAP. On the other hand, GFAP was present in most tumor cells around TN-negative, FN-positive vessels. LN was detected in all vascular and pial-glial basement membrane zone of the tissues examined. These findings indicate that the degree of histological malignancy and the degree of cell dedifferentiation of human gliomas correlate well with the expression of TN, but are inversely correlated with the expression of FN. We postulate that the expression of TN, but not of FN, plays a role in the promotion of angiogenesis in malignant gliomas.

Microsatellite instability and mutated type II transforming growth factor-β receptor gene in gliomas

Microsatellite instability has been reported in familial cancer syndrome and in various kinds of human sporadic tumors. We investigated the replication error (RER) and mutation rate of the transforming growth factor-beta type II receptor (TGF-beta RII) gene to determine the frequency of the RER+ phenotype and elucidate the relation between the mutation of the TGF-beta RII gene and RER in the tumorigenesis of glioma. We screened genomic DNA from 40 gliomas, comprised from 24 glioblastomas (GB), 11 anaplastic astrocytomas (AA) and five astrocytomas (AS) and compared the results with DNA from corresponding leukocytes. Seven of the 40 (18%) gliomas had the RER+ phenotype: five (21%) of 24 GB and two (18%) of 11 AA. In six gliomas we detected mutation of the TGF-beta RII gene. Five (71%) of seven RER+ and one (3%) of 33 RER-tumors had one A deletion in the (A)10 repeat of the TGF-beta RII gene. No mutations were detected in the (GT)3 repeat area of the TGF-beta RII gene. As the normal cells of these glioma patients had no mutations, we concluded that the mutations were somatic. We posit that the observed mutations inactivate the receptor through a frameshift mutation resulting in protein truncation. Our data suggest that the TGF-beta RII (A)10 repeat may be one area of genomic instability in the early stages of malignant glioma tumorigenesis.

Role of fibronectin-stimulated tumor cell migration in glioma invasion in vivo: clinical significance of fibronectin and fibronectin receptor expressed in human glioma tissues.

In order to clarify the role of fibronectin in glioma invasion in vivo, we analyzed the relationship between fibronectin-stimulated cell migration and adhesion in 14 primary glioma cells and the expression of fibronectin and the fibronectin receptor in the corresponding tumor tissues. The tumors comprised nine glioblastomas (GB) and five anaplastic gliomas (AG) consisting of two astrocytomas, two oligoastrocytomas and one ependymoma. All glioma cells tested in the primary cell culture were found to migrate to fibronectin in a dose-dependent manner. The extent of cell migration to fibronectin was not significantly different for the GB and AG groups. On the other hand, cell adhesion to fibronectin in the AG was much stronger than that in the GB group. Immunohistochemistry demonstrated that fibronectin positively stained in the extra-cellular matrix (ECM) in eight cases and that the fibronectin receptor was positive in tumor cell membranes in 10 cases. In addition, cellular fibronectin isoforms containing ED-A and ED-B sequences were found to be immunolocalized in the tumor cells and the ECM of GB. These isoforms were also specifically expressed in tumor vessels within tumor tissues, but not in those within normal brain tissues. Cell migration tended to be expressed more strongly by glioma cells derived from tumor tissues in which fibronectin was posi-tively immunolocalized in the ECM than from tissues with negative fibronectin in the ECM. Four glioma cells derived from GB whose tumor cells did not positively stain for fibronectin receptors migrated much less extensively to fibronectin than other glioma cells whose tissues showed positive staining for the fibronectin receptor. Of these four GB, two had loss of heterozygosity in the locus of fibronectin receptor b1 gene. These results suggest that fibronectin deposited in the extracellular matrix of tumors, which can be derived from both plasma and the tumor cell itself, strongly promotes the migration of glioma cells, and that expression of the fibronectin receptor may play a critical role in the biological behavior of the tumor cells, particularly in fibronectin-stimulated cell migration in vivo.© Kluwer Academic Publishers 1998

Isolation and expression analysis of a novel human homologue of the Drosophila glial cells missing (gcm) gene

A novel human homologue (GCMB) of the Drosophila glial cells missing gene (dGCM) was isolated using RACE. GCMB contained a gcm motif sequence and a nuclear targeting sequence similar to that of dGCM and mouse GCMb. Homology searches indicated that GCMB was located within chromosome 6p24.2. Transcripts of GCMB were detected by means of RT‐PCR in fetal brain, normal adult kidney, 3/3 medulloblastomas, 1/3 gliomas and 4/8 non‐neuroepithelial tumor cell lines. Our data suggest that humans have two homologues of gcm like mice and that human gcm genes form a novel family which may function not only during fetal development but also in the postnatal or pathological stage.

Fibronectin-mediated cell migration promotes glioma cell invasion through chemokinetic activity

In order to investigate the biological role of fibronectin in glioma cell invasion, we studied the relation between migratory responses or adhesiveness of glioma cells to fibronectin and the in vitro invasion in three human malignant glioma cell lines, A172, T98G and U373MG. All these cell lines chemotactically migrated in a dose-dependent manner to fibronectin in concentrations ranging from 0.5 to 10 µg/ml, with A172 cells showing the strongest migration and U373 cells the weakest. Checkerboard analyses demonstrated that A172 and T98G cells showed much stronger chemokinetic responses to fibronectin than U373MG cells. In contrast to the migratory responses, A172 and U373MG cells showed an almost equally high adhesion to fibronectin and T98G cells a low adhesion. The degree of expression of the integrin α5 subunit correlated well with the strength of glioma cell adhesion to fibronectin rather than that of migration to the molecule. Furthermore, the cell adhesion to fibronectin was almost completely inhibited by arginine-glycine-aspartic acid (RGD)-containing peptides, but the fibronectin-stimulated cell migration was only partially inhibited. An in vitro invasion assay disclosed that U373MG cells invaded the artificial basement membrane barrier the most and A172 cells the least. However, addition of fibronectin to the glioma cells markedly enhanced the invasive activity of A172 and T98G cells but had little effect on that of U373MG cells. These results indicate that fibronectin-stimulated migration can be one of the factors promoting invasiveness of glioma cells and that the chemokinetic activity of fibronectin may play a crucial role in glioma invasion through conferring motor-driving force on the glioma cells.

Neural cell adhesion molecule L1 in gliomas: correlation with TGF-beta and p53.

AIMS: To assess immunohistochemically whether the neural cell adhesion molecule L1, which is a member of the immunoglobulin superfamily and has been shown recently to be a stimulating factor for glioma migration, is expressed in glioma tissues, and to investigate factors that can regulate this expression. METHODS: Twenty seven glioma tissue specimens including 13 glioblastomas, seven anaplastic astrocytomas, and seven astrocytomas were examined. Immunohistochemical analyses of L1, p53, and transforming growth cell factor beta (TGF-beta) were performed on each tumour using both polyclonal and monoclonal antibodies. RESULTS: Nine (33%) specimens (six glioblastomas and three anaplastic astrocytomas) had L1 positive immunostaining. p53 positive staining was detected in 10 (43%) of 23 glioma specimens (seven glioblastomas and three anaplastic astrocytomas). TGF-beta positive immunostaining was observed in 12 (52%) of the 23 glioma specimens (six glioblastomas, four anaplastic astrocytomas, and two astrocytomas). There was a statistical correlation between both p53 and L1 expression and TGF-beta and L1 expression. No such correlation was found between p53 and TGF-beta expression. CONCLUSIONS: These results suggest that mutation of the p53 gene or expression of TGF-beta may upregulate the expression of the L1 gene, thus resulting in high grade migration of glioma cells.

Anti-proliferative effects of TNP-470 on human malignant gliomain vivo: potent inhibition of tumor angiogenesis

SummaryA novel angiogenesis inhibitor TNP-470 was investigated for its anti-tumor activity against malignant gliomas bothin vitro andin vivo. TNP-470 cytostatically inhibited the growth in all of the seven glioma cell lines in culture including anticancer drug resistant cells. The 50% inhibitory concentrations (IC50) of these glioma cell lines were 10 to 30 Μg/ml and they were 10 to 20 times higher than IC50 of normal endothelial cells. TNP-470 (30 mg/kg, i.p., every other day) also significantly inhibited the tumor growth of T98G-transplanted nude mice. Microscopically, tumor vessels after the treatment of the tumor-bearing mice with TNP-470 became fewer in number and smaller in diameter than those without treatment. Furthermore, there appeared extensive necrotic areas in the tumor with TNP-470. These results indicate that TNP-470 is a potent angiogenesis inhibitor for malignant gliomas. In addition, the studies of labeling index of BrdU and Ki67 suggest that TNP-470 may act mainly on tumor endothelial cells, thus resulting in reduction of the tumor growth.

Homozygous deletions of p16INK4A/MTS1 and p15INK4B/MTS2 genes in glioma cells and primary glioma tissues

The p16INK4A/MTS1 (p16) and p15INK4B/MTS2 (p15) genes map to 9p21 where genetic alterations have been frequently reported in various human tumors. Using the polymerase chain reaction (PCR), we investigated the loss of these genes on primary glioma samples and cultured glioma cells. All or any of three exons of the p16 gene were homozygously delted in 11 (35.5%) of 31 glioblastomas, none of 9 anaplastic astrocytomas and 5 astrocytomas, and in all 6 human glioma cell lines. Exon 2 of the p15 gene was homozygously deleted in 4 (12.9%) of 31 glioblastomas, but not in lower grade gliomas. It was homozygously deleted in 5 (83.3%) of 6 glioma cell lines. In 12 short-term cultures of cells derived from primary glioma samples, 5 (41.7%) and 2 (16.7%) glioblastoma-derived cells had homozygous deletion of all or any of the three exons of the p16 gene and exon 2 of the p15 gene, respectively. The deletion pattern of these genes in cultured cells was completely consistent with that seen in the primary tumors. Furthermore, two long-term cultures retained both genes that were identical to those in the original tumor tissues. Our results indicate that loss of the p16 and p15 genes may be involved in tumor progression in human gliomas, especially in the development of glioblastoma, that this loss may give growth advantage to the cells in culture, and that it is not the result of culture artifacts.

In vivo etoposide-resistant C6 glioma cell line: Significance of altered DNA topoisomerase II activity in multi-drug resistance

We have established an in vivo etoposide-resistant glioma cell line (C6/VP) from C6 rat glioma cells by stepwise exposure to increasing doses of etoposide. The C6/VP cells were 10 times more resistant to etoposide than the parental C6 cells. In addition C6/VP cells demonstrated cross-resistance to vincristine and vinblastine, but not to ADM or m-AMSA. Interestingly, the cells had collateral sensitivity to ACNU, cisDDP and Ara-C. The C6/VP cells did not express the MDR gene or p-glycoprotein, while they showed 16 times less topoisomerase II catalytic activity compared to the C6 cells. Although there was no significant difference between C6 and C6/VP cells in amounts of topoisomerase II in nuclear extracts, the C6/VP cells had 2.9 times higher amounts of the enzyme than C6 cells in nuclear scaffold prepared from a relatively low-salt buffer (0.5 M NaCl). Northern blot analysis demonstrated that mRNAs of topoisomerase IIα isoforms were expressed both in C6 and C6/VP cells, and that the amounts of topoisomerase IIα in C6/VP cells were 14 times greater than in C6 cells. The total uptake of etoposide in tumor tissues derived from C6/VP cells was 3 times less than those derived from parental C6 cells. These results indicate that the C6/VP acquired a multi-drug resistance phenotype by a reduction of the catalytic activity of topoisomerase II and/or diminished accumulation of drugs. This phenotype did not involve the p-glycoprotein. Alterations of topoisomerase II in the C6/VP cells also were accompanied by an increased amount of the topoisomerase IIα isoform, most of which was localized in the nuclear scaffold (matrix). This suggests that altered binding of topoisomerase II to topologically organized DNAs in the nuclear scaffold may be the molecular basis of this multi-drug resistance phenotype.

A new mutation of the L1CAM gene in an X-linked hydrocephalus family

X-linked hydrocephalus is a genetic form of hydrocephalus that frequently occurs in males. It is characterized by ventricular dilatation, mental retardation, deformity of the thumb and spastic paraparesis. Recently, 23 different mutations of the gene for the neural cell adhesion molecule, L1CAM, located at chromosome region Xq28, have been reported, 16 of which were detected in families with X-linked hydrocephalus. We sequenced the coding region of the L1CAM gene of patients from two different families with X-linked hydrocephalus and found a novel mutation at nucleotide residue 1963 in one family. This mutation from adenine to guanine results in an amino acid change from lysine to glutamic acid at residue 655 of the L1CAM protein, which belongs to the fibronectin type III domain. We report another method for the rapid identification of the mutation based on the polymerase chain reaction. This mutation was not detected among 70 X chromosomes from a healthy population. Ours is the first report demonstrating this gene mutation in X-linked hydrocephalus in an Asian population. Our findings further emphasize the evolving genotypic heterogeneity in X-linked hydrocephalus.